Major depressive disorder (MDD) is one of the most widespread mental disorders globally and a major cause of disability, affecting personal, family, professional and social aspects of patients’ lives. According to the Institute for Health Metrics and Evaluation, approximately 280 million people had depression in 2020,1 and the incidence of MDD increased by 28% following the COVID-19 pandemic, particularly among women and young people.Reference Santomauro, Mantilla Herrera, Shadid, Zheng, Ashbaugh and Pigott2 Recent research has emphasised the role of biological markers in indicating the presence and severity of MDD. These markers potentially include genetic, neuroendocrine and inflammatory indicators, which are crucial for diagnosis, guiding therapy and the development of new drugs.Reference Santosh Kore and Prabhavalkar3–Reference Strimbu and Tavel7 Over 9000 studies have investigated the immune system's role in depression, and particularly how inflammation contributes to MDD.Reference Baune8 The relationship was initially linked to depressive symptoms and increased cortisol levels resulting from disruptions in the hypothalamic-pituitary-adrenal and hypothalamic-pituitary-gonadal axes.Reference Juruena, Bocharova, Agustini and Young9,Reference Troubat, Barone, Leman, Desmidt, Cressant and Atanasova10 However, the aetiology of depression is complex, involving genetic, traumatic, environmental and psychosocial factors, which complicates the identification of specific biomarkers. Current studies are examining various biomarkers, such as cytokines and neuropeptides, focusing on neuroinflammation and elements of both the innate and adaptive immune systems.Reference Baune8,Reference Lang and Borgwardt11,Reference Roman and Irwin12 Researchers are also evaluating potential clinical immunotherapies for treating depression, rethinking the pathophysiological mechanisms primarily from an immunological perspective. The immune system is divided into two main categories: the innate and adaptive immune systems. The innate system acts as the first line of defence against antigens, primarily using macrophages to detect and destroy pathogens and produce cytokines essential for the inflammatory response. In contrast, the adaptive system, which includes T cells and B cells, mounts a more targeted and delayed response using cytokines and antibodies once specific antigens are recognised.Reference Sompayrac13 It is known that inflammatory signaling at both peripheral and central nervous system levels initiates and amplifies inflammatory processes.Reference Bentivoglio, Mariotti and Bertini14 Inflammatory signalling at both the peripheral and central nervous system levels initiates and amplifies inflammatory processes. It begins through the role of intracellular transcription factors, such as nuclear factor kappa B (NF-κB) and activator protein 1 (AP-1), which promote the expression and production of pro-inflammatory cytokines like tumor necrosis factor-alpha (TNF-α), interleukin-6 (IL-6) and interleukin-1β (IL-1β).Reference Roman and Irwin12 These cytokines increase the activity of enzymes called cyclooxygenases (COX-1 and COX-2), which subsequently raise levels of prostaglandins and intensify the inflammatory response. In the central nervous system, microglia transform into an amoeboid shape releasing pro-inflammatory cytokines, significantly affecting neurotransmitter systems and activating the mitogen-activated protein kinase (MAPK). This activation enhances the activity of presynaptic reuptake pumps for serotonin (5-HT), dopamine and norepinephrine, reducing their availability across synapses. Moreover, cytokines activate the enzyme indoleamine 2,3-dioxygenase, which converts tryptophan to kynurenine, reducing tryptophan availability for serotonin synthesis. Excess kynurenine is further metabolised by activated microglia into quinolinic acid, which stimulates the N-methyl-D-aspartate receptor (NMDAR) and promotes the release of glutamate. Pro-inflammatory cytokines lead to a decrease in glutamate reuptake and an increase in its release, which, when linked to extrasynaptic NMDAR receptors, reduces the synthesis of brain-derived neurotrophic factor (BDNF). BDNF is crucial for neuronal integrity and neurogenesis.Reference Roman and Irwin12 Cytokines, small peptides essential for cellular communication within the immune system, include interleukins, interferons, chemokines, lymphokines and the tumor necrosis factor superfamily.Reference Harsanyi, Kupcova, Danisovic and Klein15,Reference Miller16 Pro-inflammatory cytokines, such as IL-1β, IL-6, TNF-α and IL-8, are critical for initiating the immune response to infections, injuries or stress, causing typical signs of inflammation such as redness, swelling, heat and pain. In contrast, anti-inflammatory cytokines such as IL-10 and transforming growth factor-beta (TGF-β) help modulate and reduce inflammation, facilitating tissue repair and preventing excessive tissue damage. Maintaining a balance between these cytokines is critical, as an excess of pro-inflammatory cytokines can lead to chronic inflammatory diseases such as rheumatoid arthritis or autoimmune conditions, whereas a deficiency can increase susceptibility to infections.Reference Harsanyi, Kupcova, Danisovic and Klein17 Cytokines are vital in the immune response and also influence the nervous system by inducing neuroinflammation.Reference Pariante18 Some of these, studied in relation to depression, appear to play a significant role (see Table 1, adapted from Sakamoto et al).Reference Sakamoto, Zhu, Hasegawa, Karma, Obayashi and Alway19
Table 1 Cytokines and other inflammatory biomarkers associated with depression
IL, interleukin; CSF, cerebrospinal fluid; Th, T helper cells; IFN, interferon; CCL, C-C motif chemokine ligand; MCP, monocyte chemoattractant protein; MIP, macrophage inflammatory protein; RANTES, regulated upon activation, normal T cell expressed and secreted; TNF, tumor necrosis factor; TGF, transforming growth factor; BDNF, brain-derived neurotrophic factor; CRP, C-reactive protein; CXCL, C-X-C motif chemokine ligand; VEGF, vascular endothelial growth factor; IBA1, ionized calcium-binding adapter molecule 1; TLR, toll-like receptor; dsRNA, double-stranded ribonucleic acid; LPS, lipopolysaccharide.
a. Blood refers to serum or plasma samples. Brain tissue refers to tissue samples collected during autopsy or research studies.
Research implications
Researchers are studying how cytokine levels during neuroinflammation might influence the effectiveness of antidepressant treatments.Reference Liu, Wei, Strawbridge, Bao, Chang and Shi20 This connection underscores the importance of understanding cytokines not only for immune regulation, but also for their potential impact on mental health. Research has identified numerous inflammatory markers, ranging from well-studied to lesser known, that could play a role in depressive disorders.Reference Slavich and Irwin21,Reference Roman and Irwin22 The complex interplay between the immune system and psychiatric conditions has spurred research into the need for regulated anti-inflammatory responses to alleviate depressive symptoms.Reference Ridker, Hennekens, Buring and Rifai23,Reference Hänsel, Hong, Cámara and von Känel24 This interest also extends to certain genetic biomarkers that indicate a predisposition to MDD, resulting from genetic mutations that may also influence its severity.Reference Mamdani, Weber, Bunney, Burke, Cartagena and Walsh25 Studies have shown how personal attachment styles and relational dynamics modulate the functioning of the immune system and can alter levels of inflammation.Reference Ehrlich26,Reference Pietromonaco, DeBuse and Powers27 Further research has explored these interactions, confirming how specific factors such as social relationships, including social isolation, loneliness, and lack of social support, can influence the immune system.Reference Holt-Lunstad28 Attention to pro-inflammatory cytokines has led to their consideration in screening and predicting responses to antidepressant treatment.Reference Roman and Irwin12 Evidence indicates that individuals with depression who do not respond to monoamine reuptake inhibitors exhibit abnormal levels of various pro-inflammatory activity markers compared with those who respond to pharmacotherapy. This link has led to the hypothesis that, in a subpopulation of individuals with depression, the inflammatory component might be central to the depressive condition.Reference Wohleb, Franklin, Iwata and Duman29 For example, elevated levels of circulating inflammatory markers predict a poor response to selective serotonin reuptake inhibitors, whereas high levels of these markers predict an enhanced response to tricyclic antidepressants, ketamine and electroconvulsive therapy.Reference Liu, Wei, Strawbridge, Bao, Chang and Shi20,Reference Gasparini, Callegari, Lucca, Bellini, Caselli and Ielmini30,Reference Otte, Gold, Penninx, Pariante, Etkin and Fava31 In neuroinflammation, increased activity of cyclooxygenase (COX-1 and COX-2) leads to higher levels of prostaglandins, which further promote inflammation.Reference Sokol and Luster32 Therefore, inhibiting the enzymatic activity of COX-1 and COX-2 could be a target for non-steroidal anti-inflammatory drugs, proposed as new neuroimmunological treatments for cases of depression that are difficult to treat.Reference Roman and Irwin22 Emerging evidence from recent studies highlights the potential of anti-inflammatory treatments across different age groups with depression. A study in adults revealed that white blood cell counts, a broad marker of the immune system, do not predict treatment responses in bipolar disorder, indicating the complexity of immune interactions in psychiatric conditions.Reference Köhler-Forsberg, Sylvia, Bowden, Calabrese, Thase and Shelton33 Meanwhile, a meta-analysis of anti-inflammatory treatments in children and adolescents with depressive symptoms found a small but significant effect, particularly from omega-3 fatty acids, in reducing depressive symptoms. This suggests a key role for inflammatory pathways in the supplementary treatment of young individuals with depressive disorders.Reference Vöckel, Markser, Wege, Wunram, Sigrist and Koenig34 The importance of considering age as a critical variable in the diagnosis and treatment protocols for depression is emphasised. A well-known phenomenon in individuals over 50 years of age is inflammaging, characterised by chronic low-level inflammation and an increase in inflammatory cytokines during the ageing process.Reference Fulop, Larbi, Pawelec, Khalil, Cohen and Hirokawa35 This condition can have negative health consequences, as chronic inflammation in those aged over 50 years reflects an age-related alteration in the immune system, leading to an exaggerated and dysfunctional inflammatory response. Understanding inflammaging is essential for developing therapeutic strategies aimed at modulating pro-inflammatory cytokines to promote health in ageing. This also suggests the need for further longitudinal studies to explore these dynamics more thoroughly. Research consistently shows that individuals with depressive disorders exhibit higher levels of various cytokines compared with controls, with notable increases in C-reactive protein (CRP), IL-6, IL-1β and TNF-α.Reference Dowlati, Herrmann, Swardfager, Liu, Sham and Reim36–Reference Haapakoski, Mathieu, Ebmeier, Alenius and Kivimäki38 Although substantial progress has been made in understanding the immune system dysregulation in depression, many questions remain unanswered. Clinical research has yielded conflicting results regarding the efficacy of anti-inflammatory agents in treating depression.Reference Beurel, Toups and Nemeroff39 Like other neuropsychiatric disorders, depression is not a singular disease, but a heterogeneous syndrome, characterised by a variety of symptoms and diverse responses to treatments.Reference Drysdale, Grosenick, Downar, Dunlop, Mansouri and Meng40 Although increased inflammatory cytokines are observed in some patients with depression, this does not necessarily indicate that inflammation is a universal aspect of the disorder. The levels of these cytokines vary among individuals with depression, and not all individuals with elevated cytokine levels experience depression. Furthermore, factors such as body mass index and blood pressure may also affect these markers, yet their impact on the link between depression and inflammation has not been thoroughly investigated in most studies. The reasons for these variations – whether they stem from an incomplete understanding of immune system anomalies, comorbidities or a focus on specific cytokines that enhance mood – remain elusive, as does the influence of environmental factors on inflammation.Reference Beurel, Toups and Nemeroff39
The strong correlation between inflammatory processes and MDD is increasingly emphasised in the scientific literature. However, recent studies urge caution due to the complex relationship between cytokine levels in peripheral blood, cerebrospinal fluid (CSF) and nervous tissue. Therefore, we conducted a scoping review on inflammatory biomarkers in depression, which is essential not only for framing the current context but also for identifying potential gaps in the existing literature. This review systematically summarises the knowledge acquired, examining both the coherence and discrepancies between recent studies and critically evaluating their implications for clinical practice by integrating the most recent data with pre-existing evidence. This scoping review represents a crucial opportunity to synthesise a large body of research, presenting the state of the art to guide future scientific efforts in immunopsychiatry, and proposing new study hypotheses and directions for further treatments.
Method
Conceptual framework and objectives
This scoping review was conducted in accordance with the PRISMA Extension for Scoping Reviews (PRISMA-ScR) guidelines,Reference Tricco, Lillie, Zarin, O'Brien, Colquhoun and Levac41 with the aim of mapping the literature related to inflammatory biomarkers in depression, exploring the diversity of available studies and identifying key research areas. The objective was to provide a comprehensive understanding of the correlations between inflammation and depression through a variety of evidence sources and study contexts.
Search strategy
Focusing on research from the past 5 years, our objective has been to identify and assess emerging trends in the study of inflammatory biomarkers in depression, a field characterised by rapid development and significant advancements. This temporal limitation enabled us to focus on the most recent studies that address current scientific challenges, thereby ensuring a synthesis that is up-to-date with the scientific literature. The search strategy, tailored to meet the goals of this scoping review, facilitated the inclusion of a broad spectrum of research, encompassing literature reviews, randomised controlled trials (RCTs), non-RCTs and observational studies. In PubMed, our search yielded 417 relevant articles published between 1 January 2020 and 1 May 2024, using established methodologies with the search string: ‘depressive disorders AND inflammatory markers NOT covid’ across ‘All fields’. In SCOPUS, for the same period, the bibliographic search was broadened using the string in ‘TITLE-ABS-KEY’: (markers of depression-inflammation correlation) AND PUBYEAR > 2019 AND PUBYEAR < 2025 AND (LIMIT-TO (DOCTYPE,‘ar’)) AND (EXCLUDE (SUBJAREA,‘AGRI’) OR EXCLUDE (SUBJAREA,‘CENG’) OR EXCLUDE (SUBJAREA,‘EART’) OR EXCLUDE (SUBJAREA,‘COMP’) OR EXCLUDE (SUBJAREA,‘CHEM’) OR EXCLUDE (SUBJAREA,‘ENVI’) OR EXCLUDE (SUBJAREA,‘SOCI’) OR EXCLUDE (SUBJAREA,‘MULT’)) AND (LIMIT-TO (LANGUAGE,‘English’)) AND (LIMIT-TO (EXACTKEYWORD,‘Human’)), resulting in 230 records. The PsycINFO database, using the same search string and time frame as PubMed, resulted in 259 records. Conversely, in Open Grey, with the string: ‘Biomarkers of inflammation in depressive disorders’ applied within the same period, no records were found. Finally, in the Cochrane Library, a search from 1 January 2020 to 1 May 2024, with the string: ‘depressive disorders AND inflammatory markers NOT covid’ performed in the ‘Title, Abstract, Keyword’ section of the database without other restrictions, produced two reviews.
Study selection
During the study selection phase, two independent reviewers (W.P. and S.S.) anonymously screened the titles and abstracts of the retrieved articles. To ensure the impartiality of the review process and minimise the risk of bias, the identity of the study authors, their institutional affiliations and details about the study outcomes were concealed during the initial screening phase. Discrepancies between reviewers were resolved through discussion and consensus, or, if necessary, by consulting a third expert reviewer. Potentially relevant reports were then fully assessed based on explicit selection criteria. Inclusion criteria were (a) human studies, (b) investigations on patients with depression and controls, (c) publication between 2020 and 2024, and (d) assessment of inflammatory biomarkers in relation to depression. Exclusion criteria included (a) non-human context, (b) reporting duplication, (c) studies where quantitative assessments of inflammation markers had not been performed, (d) studies concerning SARS-CoV-2 disease as a confounding factor and (e) studies on paediatric and geriatric populations.
Data extraction and quality assessment
Data extraction and the assessment of the quality of the included studies were conducted by two blinded reviewers (W.P. and S.S.), using predefined electronic forms, ensuring consistency and accuracy across the review process. The reviewers independently collected specific information, such as authors, publication year, study context and main findings, according to a standardised template. This aimed to systematically capture the essential aspects of each study regarding inflammatory biomarkers in depression, facilitating the identification of common themes, trends and existing research gaps. Simultaneously, the quality of each study was evaluated to ensure the reliability of the findings, with any discrepancies between reviewers resolved through discussion and consensus. This combined approach aligns with the scoping review's goals, focusing on comprehensively mapping out the field without conducting a formal quality evaluation of individual studies.
Our search yielded a total of 908 potentially relevant records. Of these, 190 were excluded as duplicates, and 608 were excluded based on their titles or abstracts as they were not relevant. The remaining 110 studies underwent a more detailed assessment, resulting in the exclusion of 66 articles because they did not meet the inclusion criteria. Ultimately, 44 studies met the inclusion criteria (see Fig. 1). This search was conducted up to 1 May 2024. All articles that met the inclusion criteria are reviewed here. Applying the PRISMA-ScR guidelines enhanced the transparency and systematic nature of our scoping review, enabling us to effectively explore the field of study.
Fig. 1 PRISMA flow diagram of the study selection process.
Results
Our comprehensive analysis of 44 studies, including 30 observational studies, 2 RCTs and 12 reviews, confirmed a clear association between elevated levels of inflammatory biomarkers and the presence of depressive symptoms across various subtypes of major depression (melancholic, atypical, anxious) and different states of remission.Reference Pedraz-Petrozzi, Neumann and Sammer42–Reference Zeng, Li, Chen, You, Mai and Lan48 For a complete summary of the results, see Tables 2–4. Details of these studies are given below.
Table 2 Review studies
MDD, major depressive disorder; CRP, C-reactive protein; IL, interleukin; BDNF, brain-derived neurotrophic factor; TNF, tumor necrosis factor; HRSD, Hamilton Rating Scale for Depression; IRS, inflammatory response system; ECT, electroconvulsive therapy; CSF, cerebrospinal fluid.
Table 3 Observational studies
MDD, major depressive disorder; CRP, C-reactive protein; TNF, tumor necrosis factor; IL, interleukin; CSF, cerebrospinal fluid; CXCL, C-X-C motif chemokine ligand; sTNFR, soluble tumour necrosis factor receptor; BDI-FS, Beck Depression Inventory-Fast Screen; MARS, medication adherence rating scale; STAR*D, sequenced treatment alternatives to relieve depression; AUC, area under the curve; CCL, C-C motif chemokine ligand; HRSD, Hamilton Rating Scale for Depression; BMI, body mass index; ELISA, enzyme-linked immunosorbent assay; MIF, Macrophage Migration Inhibitory Factor; MADRS, Montgomery–Åsberg depression rating scale; MIP, macrophage inflammatory protein; NOX1, NADPH oxidase 1; NfL, neurofilament light chain; P1NP, N-terminal propeptide of type 1 procollagen; BDI-II, Beck Depression Inventory-II; hsCRP, high-sensitivity C-reactive protein.
Table 4 Randomised controlled trials
IL, interleukin; TNF, tumor necrosis factor; MDD, major depressive disorder; BDNF, brain-derived neurotrophic factor.
IL-1β
IL-1β plays a significant role in depression. It has been detected in various tissues, including blood, cerebrospinal fluid, and brain tissues, and elevated levels have been observed in patients with depression. The increase in IL-1β can affect neurotransmitters and contribute to the activity of other neuroinflammatory pathways, thereby contributing to the pathogenesis of depression.Reference Carniel and da Rocha43,Reference Elgellaie, Thomas, Kaelle, Bartschi and Larkin46,Reference Debnath, Berk and Maes52,Reference Chang, Jiang, Shan, Zhang, Li and Qi58,Reference Brunoni, Supasitthumrong, Teixeira, Vieira, Gattaz and Benseñor61,Reference Liu, Yuan, Wu, Xu, Wang and Meng85
IL-6
IL-6 was identified as a strong indicator of the severity of depressive symptoms compared with healthy controls, with a significant correlation to anhedonia and reduced motivation. Both longitudinal and cross-sectional studies have demonstrated that high concentrations of IL-6 are associated with an increased likelihood of depressive symptoms, particularly in patients with a high body mass index.Reference Ye, Kappelmann, Moser, Smith, Burgess and Jones50,Reference Palmos, Chung, Frissa, Goodwin, Hotopf and Hatch69,Reference Foley, Slaney, Donnelly, Kaser, Ziegler and Khandaker82 Further studies have extended this correlation to CRP levels, linking IL-6 and CRP to depressive symptoms such as sadness, loss of interest and difficulty concentrating.Reference Frank, Jokela, Batty, Cadar, Steptoe and Kivimäki65
CRP
Various research has shown that high levels of CRP are consistently linked to an increased risk of depressive symptoms, particularly affecting appetite and concentration. The analysis of large samples indicates that CRP is a strong predictor of depression, emphasising the central role of systemic inflammation in the pathogenesis of depression.Reference Pitharouli, Hagenaars, Glanville, Coleman, Hotopf and Lewis67,Reference Lan, Zhou, Wu, Wu, Zhan and Wang68,Reference Moilanen, Liukkonen, Jokelainen, Keinänen-Kiukaanniemi, Puukka and Timonen83 Other studies have shown that high plasma CRP levels and increased TNF and soluble IL-6 receptors in the CSF are associated with severe depressive symptoms such as anhedonia and reduced motivation.Reference Debnath, Berk and Maes52,Reference Kopra, Mondelli, Pariante and Nikkheslat53,Reference Felger, Haroon, Patel, Goldsmith, Wommack and Woolwine60,Reference Lan, Zhou, Wu, Wu, Zhan and Wang68,Reference Moilanen, Liukkonen, Jokelainen, Keinänen-Kiukaanniemi, Puukka and Timonen83
TNF-α
Some studies have highlighted that elevated levels of TNF-α, IL-8 and macrophage inflammatory protein 1β (MIP-1β) in plasma are correlated with worse performance on processing speed and working memory tests in patients with MDD and obesity.Reference Lan, Wang, Li, Chao, Lao and Wu75 The interaction between TNF-α and fatigue in patients with depression suggests a direct influence on physical symptoms of depression.Reference Milaneschi, Allers, Beekman, Giltay, Keller and Schoevers62,Reference Kappelmann, Czamara, Rost, Moser, Schmoll and Trastulla64,Reference Mandal, Spoorthy, Godi, Nanda, Mukherjee and Mishra80 However, another study, despite identifying significant associations between levels of CRP and IL-6 and depressive symptoms, noted no such association for TNF-α, suggesting a selective relevance of certain cytokines in depression.Reference Mac Giollabhui, Ng, Ellman and Alloy51
Imaging studies and neuroinflammation
It has been documented that peripheral inflammation associated with high levels of CRP affects specific brain regions critical for managing depressive states, with elevated serum levels associated with thinner cortical regions such as the left superior frontal gyrus and left insula.Reference Green, Shen, Stevenson, Conole, Harris and Barbu71 These observations are corroborated by a review, highlighting how pro-inflammatory markers can cause demyelinating effects on white matter, compromising its integrity and representing a pro-inflammatory condition associated with a severe depressive course resistant to treatment.Reference Breit, Mazza, Poletti and Benedetti55 At the same time, another study has identified inflammation as a risk factor for the development or relapse of MDD, with a significant impact, particularly in demographic groups such as women over 50 years of age.Reference Zainal and Newman70 These studies collectively demonstrate an important connection between inflammation, biochemical dysfunctions and damage to white matter in various forms of depression, opening new perspectives for research.
Other pro-inflammatory markers in mood disorders
Elevated levels of pro-inflammatory cytokines such as IL-17, IL-21 and IL-23, and reduced levels of IL-35, have been frequently observed in patients with MDD compared with healthy controls, suggesting an enhanced pro-inflammatory gene expression.Reference Gałecka, Bliźniewska-Kowalska, Orzechowska, Szemraj, Maes and Berk63 Emphasising the role of cytokines and the immune response in the pathogenesis of depression, another study demonstrated a significant increase in serum levels of IL-12 and IL-4 in patients with MDD, with a positive correlation between these cytokine levels and the severity of depression.Reference Sarmin, Roknuzzaman, Mouree, Islam and Al Mahmud84
Differences in biomarkers between bipolar disorder and MDD
Monitoring of inflammatory biomarkers has played a crucial role in distinguishing between bipolar disorder and MDD, identifying significant differences in biomarker levels between these conditions.Reference Poletti, Vai, Mazza, Zanardi, Lorenzi and Calesella66,Reference Czysz, Mason, Li, Chin-Fatt, Minhajuddin and Carmody72 Markers such as IL-9, TNF-α, C-C motif chemokine ligand (CCL)3, CCL4, CCL5, CCL11, CCL25, CCL27, C-X-C motif chemokine ligand (CXCL)6 and CXCL11 have been indicative of bipolar disorder, whereas IL-1β, IL-2, IL-4, IL-6, IL-7, IL-10, IL-16, CCL20, CCL21, CXCL12, platelet-derived growth factor subunit B and vascular endothelial growth factor are more frequently associated with MDD. Research a year earlier on depression and bipolar disorder also found higher levels of IL-1β, TNF-α, soluble tumour necrosis factor receptor (sTNFR)1, IL-12 and IL-10 in patients with MDD, compared with higher levels of IL-6, sTNFR2, IL-18, IL-33, soluble suppression of tumourigenicity 2 and neuroprotective gene modulator KLOTHO in patients with bipolar disorder.Reference Brunoni, Supasitthumrong, Teixeira, Vieira, Gattaz and Benseñor61
Role of macrophages and oxidative stress
The macrophage migration inhibitory factor (MIF) and oxidative stress have been explored as potential markers of antidepressant treatment efficacy, indicating that these factors may play a role in the responses to antidepressant treatment.Reference Swoboda, Deloch, von Zimmermann, Richter-Schmidinger, Lenz and Kornhuber74 Concurrently, another study investigated the role of oxidative stress by examining the serum levels of two potential biomarkers that might be involved in the pathophysiology of MDD: NOX1, also known as NADPH oxidase 1, an enzyme involved in various physiological and pathological processes, including oxidative stress and inflammation; and Raftlin, a protein important in cellular processes, including those related to oxidative stress and inflammation.Reference Hursitoglu, Kurutas, Strawbridge, Oner, Gungor and Tuman78
Tryptophan metabolism and neuroinflammation
Studies on how alterations in tryptophan metabolism affect neuroinflammation have confirmed a reduction in serotonin levels in favour of kynurenine, which exacerbates depressive symptoms.Reference Milaneschi, Allers, Beekman, Giltay, Keller and Schoevers62,Reference Comai, Melloni, Lorenzi, Bollettini, Vai and Zanardi73 These metabolic changes may also correlate with structural damage to white matter, suggesting potential treatment resistance in cases of severe depression.
Cognitive impact of inflammation
It has been demonstrated how inflammation affects cognitive function and brain structure, through biomarkers such as neurofilament light chain (NfL) and the N-terminal propeptide of type 1 procollagen (P1NP), which show a correlation with the severity of symptoms and cognitive decline in patients with mood disorders.Reference Bai, Liu, Kuo, Tsai, Hsu and Huang79
Therapeutic implications and treatment responses
Cognitive–behavioural therapy-based interventions have been shown to reduce symptoms of depression, anxiety and sleep difficulties, consequently lowering inflammatory markers such as IL-1β, IL-6, IL-8, TNF-α and increasing levels of BDN.Reference Liu, Yuan, Wu, Xu, Wang and Meng85 A similar conclusion has been reached by other studies, which have highlighted the use of psychotherapies, anti-inflammatory drugs and nutritional strategies to reduce inflammation for the improvement of depressive symptoms.Reference Harsanyi, Kupcova, Danisovic and Klein54,Reference Réus, Manosso Luana, Quevedo and Carvalho56 A direct link between inflammation and the efficacy of depression treatment is also suggested by improved responses to antidepressant treatments associated with high levels of IL-13.Reference Czysz, Mason, Li, Chin-Fatt, Minhajuddin and Carmody72 Recently, the hypothesis of the pathogenic role of inflammation in depression has been strengthened, indicating that high cytokine levels are linked to the severity of the disorder, particularly prevalent in treatment-resistant depression. These findings promote the use of anti-inflammatory therapies as promising strategies to manage cases of treatment-resistant depression.Reference Chang, Jiang, Shan, Zhang, Li and Qi58
New research perspectives
The use of extracellular vesicles derived from astrocytes has provided new insights into glial inflammation in depression, suggesting that astrocytes can be a useful tool for analysing the state of astrocytes in human patients.Reference Chang, Jiang, Shan, Zhang, Li and Qi58
Application of artificial intelligence in depression classification through inflammatory biomarkers
Machine learning techniques have been utilised to distinguish between patients with depression and healthy individuals, highlighting the effectiveness of immunometabolic markers and lifestyle-related factors in classifying various forms of depression. These findings demonstrate how these tools can offer new perspectives in the recognition and management of depression, and underscore the central role of cytokines and the immune response in the pathogenesis of the disorder.Reference Xie, Lai, Xu, Di Forti, Zhang and Chen77,Reference Sánchez-Carro, de la Torre-Luque, Leal-Leturia, Salvat-Pujol, Massaneda and de Arriba-Arnau81 These data illustrate the complexity and specificity of the immuno-inflammatory mechanisms in depression, and underscore the importance of more targeted and sophisticated diagnostic and therapeutic approaches.
However, the studies under review also reveal several significant limitations that could influence the interpretation of the results.
Variability in measurement method
The techniques used to measure inflammatory biomarkers vary significantly between studies, potentially affecting the comparability of results. Some studies use peripheral blood samples, whereas others examine markers in CSF or through brain imaging, which may not reliably reflect neuroinflammatory conditions.Reference Debnath, Berk and Maes52,Reference Kopra, Mondelli, Pariante and Nikkheslat53,Reference Lan, Zhou, Wu, Wu, Zhan and Wang68
Limits of correlation between peripheral and central cytokines
Recent research has indicated that the correlation between cytokine levels in the blood and CSF is less direct than previously assumed.Reference Gigase, Smith, Collins, Moore, Snijders and Katz57 It has been reported that, despite correlations in specific subgroups, peripheral biomarkers generally do not reliably match those in the CSF, limiting their use as direct indicators of brain inflammation. This challenges the use of peripheral cytokines as accurate reflections of neuroinflammatory conditions, highlighting the need for further research to clarify these dynamics and improve diagnostic methodologies.
Study design and causality
Many of the studies included in this scoping review are cross-sectional observational studies, which limits the ability to establish causal relationships between levels of inflammatory biomarkers and depressive symptoms. For example, it is unclear whether inflammation causes depression or vice versa.Reference Liu, Wu, Wang, Liu, Peng and Wu44–Reference Elgellaie, Thomas, Kaelle, Bartschi and Larkin46,Reference Varghese, Chand, Varghese, Singh and Yadav59–Reference Gałecka, Bliźniewska-Kowalska, Orzechowska, Szemraj, Maes and Berk63,Reference Comai, Melloni, Lorenzi, Bollettini, Vai and Zanardi73,Reference Lan, Wang, Li, Chao, Lao and Wu75
Generalisability of results
Studies focus on specific populations or demographic groups, which limits the generalisability of the results to broader or different contexts than those studied. For example, some findings may not be applicable to populations with different ethnic backgrounds or health conditions.Reference Varghese, Chand, Varghese, Singh and Yadav59,Reference Felger, Haroon, Patel, Goldsmith, Wommack and Woolwine60,Reference Gałecka, Bliźniewska-Kowalska, Orzechowska, Szemraj, Maes and Berk63,Reference Lan, Zhou, Wu, Wu, Zhan and Wang68,Reference Zainal and Newman70
Overlap between conditions
Many patients with major depression may also suffer from other medical conditions that could influence levels of inflammatory biomarkers, introducing potential confounders into the study results.Reference Gałecka, Bliźniewska-Kowalska, Orzechowska, Szemraj, Maes and Berk63,Reference Lan, Zhou, Wu, Wu, Zhan and Wang68,Reference Palmos, Chung, Frissa, Goodwin, Hotopf and Hatch69
Timing and dynamics of inflammation
The temporal dynamics of inflammation in relation to the onset and progression of depressive symptoms are not yet fully understood.Reference Zainal and Newman70,Reference Lan, Wang, Li, Chao, Lao and Wu75,Reference Foley, Slaney, Donnelly, Kaser, Ziegler and Khandaker82 This uncertainty necessitates further longitudinal studies to determine whether inflammation precedes, coincides with or follows the development of depressive symptoms. Incorporating these limitations into the results helps to better contextualise the findings and suggests areas for future research, which are crucial for refining our understanding of the link between inflammation and depression, and for developing more effective and targeted treatment strategies.
Discussion
Previous studies have established an almost constant link between depression and the presence of inflammatory elements in both the innate and adaptive immune systems. Our understanding of the role of inflammatory biomarkers in MDD has significantly evolved, revealing a complex connection between systemic inflammation and the clinical manifestations of depression.Reference Breit, Mazza, Poletti and Benedetti55 This hypothesis suggests that inflammatory processes may trigger, exacerbate or sustain depression; however, the temporal sequence of inflammation relative to the onset and progression of depressive symptoms remains uncertain.Reference Foley, Slaney, Donnelly, Kaser, Ziegler and Khandaker82 In particular, intensified cytokine responses to pathogens and stress have been observed in patients with depression, which, when combined with other predisposing factors, can lead to prolonged inflammation and the dysregulation of various physiological axes.Reference Felger, Haroon, Patel, Goldsmith, Wommack and Woolwine60,Reference Lan, Wang, Li, Chao, Lao and Wu75 Although inflammatory cytokines have been extensively studied, the correlation between specific biomarkers and clinical symptoms remains complex and influenced by biological, psychological and environmental factors.Reference Brunoni, Supasitthumrong, Teixeira, Vieira, Gattaz and Benseñor61,Reference Gałecka, Bliźniewska-Kowalska, Orzechowska, Szemraj, Maes and Berk63,Reference Poletti, Vai, Mazza, Zanardi, Lorenzi and Calesella66,Reference Czysz, Mason, Li, Chin-Fatt, Minhajuddin and Carmody72,Reference Sarmin, Roknuzzaman, Mouree, Islam and Al Mahmud84 Our scoping review has identified numerous studies that highlight a growing consensus on the role of IL 1β, IL-6, TNF-α and CRP in modulating the severity and treatment response of depression.Reference Debnath, Berk and Maes52,Reference Felger, Haroon, Patel, Goldsmith, Wommack and Woolwine60,Reference Frank, Jokela, Batty, Cadar, Steptoe and Kivimäki65 The latest research emphasises the role of the cytokines IL-6 and TNF-α, correlated with greater severity of depressive symptoms, including anhedonia and reduced motivation, particularly when CRP levels are elevated.Reference Elgellaie, Thomas, Kaelle, Bartschi and Larkin46–Reference Zeng, Li, Chen, You, Mai and Lan48 Furthermore, IL-6 not only signals the presence of depression, but can also indicate resistance to conventional antidepressant treatments, suggesting the need for personalised therapeutic strategies.Reference Palmos, Chung, Frissa, Goodwin, Hotopf and Hatch69,Reference Foley, Slaney, Donnelly, Kaser, Ziegler and Khandaker82 These findings broaden our understanding of the role of inflammation in depression and may guide the development of more targeted and effective interventions. Imaging studies have revealed that chronic inflammation can impair neuroplasticity, reducing the brain's ability to form new synaptic connections and restructure existing ones. This deterioration is particularly pronounced in brain areas critical for mood and cognitive regulation, such as the left superior frontal lobe, left insula and left superior temporal lobe. A direct correlation has been observed between high levels of serum CRP and cortical thinning in these regions.Reference Ye, Kappelmann, Moser, Smith, Burgess and Jones50,Reference Réus, Manosso Luana, Quevedo and Carvalho56,Reference Felger, Haroon, Patel, Goldsmith, Wommack and Woolwine60,Reference Milaneschi, Allers, Beekman, Giltay, Keller and Schoevers62,Reference Kappelmann, Czamara, Rost, Moser, Schmoll and Trastulla64,Reference Zainal and Newman70,Reference Comai, Melloni, Lorenzi, Bollettini, Vai and Zanardi73,Reference Lan, Wang, Li, Chao, Lao and Wu75,Reference Mandal, Spoorthy, Godi, Nanda, Mukherjee and Mishra80,Reference Liu, Yuan, Wu, Xu, Wang and Meng85 Concurrently, alterations in tryptophan metabolism that increase the production of kynurenine at the expense of serotonin further exacerbate depressive symptoms. These biochemical changes illustrate a mechanism through which inflammation can worsen depression, creating a vicious cycle of inflammatory response and neuropsychological deterioration.Reference Milaneschi, Allers, Beekman, Giltay, Keller and Schoevers62,Reference Comai, Melloni, Lorenzi, Bollettini, Vai and Zanardi73 The hypothalamic-pituitary-adrenal axis, sensitive to the effects of inflammation, can also influence the development and course of depression, confirming a further connection between inflammatory responses and psychiatric dysfunctions.Reference Pedraz-Petrozzi, Neumann and Sammer42 The use of large databases such as the UK Biobank has allowed for the examination of the impact of inflammation on a large scale, revealing how age can affect the inflammatory response and the severity of depressive symptoms, especially in individuals over 50 years old. These individuals also tend to show a stronger correlation between the levels of cytokines such as IL-6 and CRP and the severity of depressive symptoms.Reference Ye, Kappelmann, Moser, Smith, Burgess and Jones50 This phenomenon, often attributed to an increase in systemic inflammation owing to ageing, known as ‘inflammaging’, is enhanced by immune changes that accumulate with chronic stress over the lifespan. It has been confirmed that inflammation may represent a potential risk factor for the development or relapse of MDD, highlighting the need for personalised treatment strategies that consider age and other demographic factors.Reference Zainal and Newman70 This reinforces the importance of further longitudinal and interventional studies that include age as a key variable. Another critical aspect is the treatment and management of depression based on biomarker levels. The use of anti-inflammatory pharmacotherapy has been proposed, particularly in cases resistant to conventional treatment,Reference Chang, Jiang, Shan, Zhang, Li and Qi58 whereas other research groupsReference Réus, Manosso Luana, Quevedo and Carvalho56 highlight the importance of integrating anti-inflammatory and nutritional approaches in the treatment of depression. Recently, it has been shown how mindfulness-based cognitive therapy can reduce symptoms of depression, anxiety and sleep disturbances, linking these improvements to a decrease in inflammatory markers such as IL-1β, IL-6, IL-8, TNF-α and increased BDNF.Reference Liu, Yuan, Wu, Xu, Wang and Meng85 These results suggest a link between psychotherapeutic interventions and biological changes, opening prospects for reverse treatments, such as anti-inflammatory ones, to improve symptoms. Some researchers, also explored how antidepressants affect the inflammatory response.Reference Swoboda, Deloch, von Zimmermann, Richter-Schmidinger, Lenz and Kornhuber74 The integration of anti-inflammatory treatments and psychotherapeutic interventions has shown potential in reducing depressive symptoms and lowering levels of inflammatory cytokines in the blood, demonstrating that it is possible to positively influence both the psychological and biological aspects of the disease. Although the potential to personalise treatment based on biomarker levels is promising, individual variability in response to antidepressant treatments and the complexity of the inflammatory pathways involved make this a complex area that requires further research. Longitudinal studies and RCTs will be crucial to determine whether modifications to inflammatory pathways can indeed improve clinical and therapeutic outcomes in these patients. Despite these significant prospects, it is important to highlight the considerable methodological limitations that might affect the interpretation of the results. Most studies on biomarkers in depression rely on cross-sectional and observational designs, which, although useful for identifying associations, are incapable of establishing causality. This is particularly relevant because cross-sectional designs cannot discern whether inflammation is a cause or a consequence of depression. The generalisability of the results is limited because the studies focus on specific populations or demographic groups. This implies that the results may not be applicable to broader or different contexts than those studied, such as populations with different ethnic backgrounds or health conditions.Reference Varghese, Chand, Varghese, Singh and Yadav59,Reference Felger, Haroon, Patel, Goldsmith, Wommack and Woolwine60,Reference Gałecka, Bliźniewska-Kowalska, Orzechowska, Szemraj, Maes and Berk63,Reference Lan, Zhou, Wu, Wu, Zhan and Wang68,Reference Zainal and Newman70 Variation in detection techniques and differences in the cohorts studied further reduce the ability to generalise the results. For example, the protocols for measuring biomarkers vary widely: some studies measure these markers in peripheral blood samples, whereas others analyse them in CSF or investigate them through brain imaging techniques. Such methodological differences can generate inconsistent and sometimes contradictory results, making comparisons and data synthesis complex.Reference Debnath, Berk and Maes52,Reference Kopra, Mondelli, Pariante and Nikkheslat53,Reference Breit, Mazza, Poletti and Benedetti55,Reference Lan, Zhou, Wu, Wu, Zhan and Wang68,Reference Green, Shen, Stevenson, Conole, Harris and Barbu71,Reference Swoboda, Deloch, von Zimmermann, Richter-Schmidinger, Lenz and Kornhuber74 However, the main concern remains the validity of measuring brain inflammation through peripheral biomarkers. A recent meta-analysis has raised important questions about the accuracy with which cytokine levels in peripheral blood can represent inflammation in the CSF.Reference Gigase, Smith, Collins, Moore, Snijders and Katz57 The conclusions suggest that, although some correlations may be found in specific patient subgroups, generally, peripheral inflammatory biomarkers do not reliably correspond to those in the CSF, thus questioning the use of such measurements as direct indicators of cerebral inflammation. This implies a need for greater caution in interpreting these markers as diagnostic tools in depression and calls for further research to develop more precise and representative measurement methodologies for inflammation at the level of the central nervous system. The necessity for extensive and standardised studies is indispensable to validate the diagnostic and therapeutic utility of inflammatory biomarkers.
Concluding the discussion, the complexity of the relationship between inflammation and MDD is confirmed, suggesting greater caution in the use of peripheral inflammatory biomarkers as indicators of neuroinflammation. It underscores the need for careful interpretation of peripheral cytokine measurements, where methodological variability and confounding factors may influence the results, thereby complicating the establishment of direct correlations between peripheral and central brain cytokine levels. Further research is essential to enhance measurement techniques for biological mechanisms and to integrate these findings with psychosocial and environmental factors. Together, these elements significantly contribute to the complexity of MDD and its therapeutic management.
This review highlighted the growing interest in inflammatory biomarkers in depression, as demonstrated by the increasing number of studies and scientific research published in recent years. However, the scientific literature on this topic exhibits several biases. First, the geographic origin of most studies is predominantly limited to Europe, Asia and North America. Second, there is a lack of consistency in the methods employed and the conclusions drawn, making it challenging to compare results and reach definitive conclusions. Third, the correlation between cytokine levels in blood and cerebrospinal fluid is less straightforward than previously thought, and there is significant overlap between medical conditions that could influence levels of inflammatory biomarkers. The reviewed studies demonstrate that inflammation is not merely a peripheral phenomenon but profoundly influences the neurological and psychological processes underlying depression.
Complexity of inflammatory biomarkers
Our study reveals a complex link between inflammation and MDD, highlighting both the challenges and opportunities associated with using inflammatory biomarkers for the diagnosis and potential treatment of this disorder. Inflammatory biomarkers, such as IL-1β, IL-6, TNF-α and CRP, have emerged as significant indicators of systemic inflammation associated with MDD. Along with other markers, they reveal their multifaceted nature and the complexity of interactions within the nervous system, underscoring the intricate relationship between inflammatory processes and depressive pathology. However, the correlation between the levels of these biomarkers in peripheral blood and CSF remains uncertain. This highlights the need to advance the precision of measurement methodologies to ensure that the assessment of cerebral inflammation is accurate and reliable.
Future research directions
It is essential to conduct longitudinal and interventional studies with a broader range of markers and patient populations to validate the role of inflammatory biomarkers in MDD. Incorporating machine learning can help analyze large datasets, identify new biomarkers undetectable by traditional methods, and recognize early signs of depression before clinical symptoms appear. These studies should aim to clarify the causal links between inflammation and depression and optimize anti-inflammatory treatments for the disorder.
Personalisation of treatment
The heterogeneity of inflammatory responses among patients with MDD underscores the need for personalised treatment strategies. Integrating therapeutic approaches that specifically target inflammatory pathways could significantly improve treatment efficacy, especially for those patients with forms resistant to conventional treatments.
Implications for clinical practice
Clinicians should consider inflammation as a significant factor in the management of MDD, utilising information on inflammatory biomarkers to guide treatment decisions. Adopting a model of personalised medicine could not only enhance clinical outcomes, but also offer new insights into the understanding and treatment of depression.
Biomarker research in MDD faces numerous challenges, including an insufficient understanding of the aetiopathogenesis of the disorder, its notable heterogeneity, frequent comorbidities and the variable specificity of biomarkers. Additionally, the current methods and detection techniques present significant obstacles. The variability in biomarker measurements and the difficulty in correlating peripheral with central inflammation indicate an urgent need to refine these methodologies. Developing panels of advanced biomarkers and evaluating them through the use of new technologies could offer effective solutions to overcome these barriers, thus improving the accuracy and reliability of diagnoses and treatments in MDD.
Data availability
The data supporting the findings of this scoping review are available upon reasonable request from the corresponding author, W.P.
Author contributions
S.S. and W.P. contributed equally to the study design, data analysis, manuscript writing and final approval of the manuscript. Each author has read and agreed to the published version of the manuscript.
Funding
This study received no specific grant from any funding agency, commercial or not-for-profit sectors.
Declaration of interest
None.
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